EP2541155B1

EP2541155B1 - Heating system, and heating system control method

Info

Publication number: EP2541155B1
Application number: EP12748144.8A
Authority: EP
Inventors: Masaru Fukuoka; Shinichi Takasaki; Gaku Hayashida
Original assignee: Panasonic Intellectual Property Management Co Ltd
Current assignee: Panasonic Intellectual Property Management Co Ltd
Priority date: 2011-04-26
Filing date: 2012-04-18
Publication date: 2016-02-24
Anticipated expiration: 2032-04-18
Also published as: JPWO2012147311A1; EP2541155A4; JP5090580B1; WO2012147311A1; EP2541155A1

Description

[Technical Field]

The present invention relates to heating systems, and particularly to a heat pump heating system.

[Background Art]

With the goal of equalizing the power load, energy suppliers in some European countries (such as Germany), as per contract, externally enforce a stop of electricity delivery (hereinafter shut-off) to heat pump heating systems for a predetermined period of time (hereinafter shut-off period, SOP) a predetermined number of times per day, offering in return a reduced energy rate.
In order to accommodate this external control, manufacturers of heat pump heating systems provide a relay switch in the system which turns the power on or off when a ripple signal is received from the energy supplier.

[Citation List]

[Patent Literature] Document JP 2005030705 discloses a heating system according to the preamble of claims 1 and 14.

[PTL 1] Japanese Unexamined Patent Application Publication No. 2009-204298
[PTL 2] Japanese Unexamined Patent Application Publication No. 2009-204299

[Summary of Invention]

[Technical Problem]

However, with the foregoing control method, the heat pump heating system is immediately shut off when a shut-off signal is received from the energy supplier. Consequently, room temperature decreases as time passes. As such, there is a concern that the comfort of the user will be compromised. When power is shut off when not enough heat has been stored in the storage tank or within the housing frame in particular, room temperature decreases significantly, causing discomfort for the user. In this case, a problem arises when the heat pump heating system is installed in a home having poor thermal insulation efficiency.
Thus, in light of the foregoing information, an object of the present invention is to provide a heat pump heating system and a heat pump heating system control method that can adequately store heat needed for the period when the supply of power is temporarily stopped by the shut-off signal.

[Solution to Problem]

The heating system according to an embodiment of the present invention receives power from a power supply source and maintains a temperature of a target to within a predetermined temperature range including a predetermined set temperature. Specifically, the heating system includes: a heat pump unit configured to generate heat using power supplied from the power supply source; a radiator unit configured to radiate the heat generated by the heat pump unit to the target; and a heating system control unit configured to cause the heat pump unit to stop generating the heat during a predetermined shut-off period, and to cause the heat pump unit to generate additional heat as shut-off period (SOP) heat in periods before and after the shut-off period, the SOP heat being an amount of heat required to be radiated during the shut-off period by the radiator unit to maintain the set temperature of the target. Also, the heating system control unit is configured to cause the generation of the SOP heat to be divided between the periods before and after the shut-off period such that a peak value of power consumption in each of the periods before and after the shut-off period is at or below a permissible peak power.
It is to be noted that general or specific embodiments may be realized as a system, method, integrated circuit, computer program, storage media, or any elective combination thereof.

[Advantageous Effects of Invention]

With the present invention, since the generation of SOP heat is divided then generated such that the peak power consumption values in each of the periods before and after of the shut-off period are at or below the permissible peak power, in addition to maintaining comfort, peaks in energy can equalized throughout the periods before and after the shut-off period.

[Brief Description of Drawings]

[FIG. 1] FIG. 1 is a diagram showing the heat pump heating system according to the first embodiment.
[FIG. 2] FIG. 2 is a block diagram showing the heat pump heating device and the heating system control unit according to the first embodiment in detail.
[FIG. 3] FIG. 3 is a flow chart illustrating the processes involved in generating the operation plan for the heat pump heating device according to the first embodiment.
[FIG. 4A] FIG. 4A is a table showing a power consumption prediction result when the pre-SOP goal room temperature is 24 degrees Celsius.
[FIG. 4B] FIG. 4B is a table showing a calculation result of the peak overall power consumption value for each of the pre-SOP goal room temperatures.
[FIG. 5A] FIG. 5A is a graph showing shifts in heat pump (HP) heat output and room temperature for each of the pre-SOP goal room temperatures.
[FIG. 5B] FIG. 5B is a graph showing shifts in power consumption for each of the pre-SOP goal room temperatures.
[FIG. 6] FIG. 6 is a flow chart illustrating the processes involved in generating the operation plan for the heat pump heating device according to the second embodiment.
[FIG. 7] FIG. 7 is a table showing a calculation result of the peak overall power consumption value for each of the pre-SOP goal room temperatures.
[FIG. 8] FIG. 8 is a flow chart illustrating the processes involved in generating the operation plan for the heat pump heating device according to the third embodiment.
[FIG. 9A] FIG. 9A is a graph showing shifts in HP heat output and room temperature for each of the pre-SOP goal room temperatures.
[FIG. 9B] FIG. 9B is a graph showing shifts in power consumption for each of the pre-SOP goal room temperatures.
[FIG. 10] FIG. 10 is a table showing a calculation result of the peak overall power consumption value for each of the pre-SOP goal room temperatures.
[FIG. 11] FIG. 11 is a table showing an example of the permissible peak power which varies depending on flooring surface area.
[FIG. 12] FIG. 12 is a table showing an example of the permissible peak power which varies depending on the rated capacity of the heat pump heating device.

[Description of Embodiments]

The heating system according to an embodiment of the present invention receives power from a power supply source and maintains a temperature of a target to within a predetermined temperature range including a predetermined set temperature. Specifically, the heating system includes: a heat pump unit configured to generate heat using power supplied from the power supply source; a radiator unit configured to radiate the heat generated by the heat pump unit to the target; and a heating system control unit configured to cause the heat pump unit to stop generating the heat during a predetermined shut-off period, and to cause the heat pump unit to generate additional heat as shut-off period (SOP) heat in periods before and after the shut-off period, the SOP heat being an amount of heat required to be radiated during the shut-off period by the radiator unit to maintain the set temperature of the target. Also, the heating system control unit is configured to cause the generation of the SOP heat to be divided between the periods before and after the shut-off period such that a peak value of power consumption in each of the periods before and after the shut-off period is at or below a permissible peak power.
With the configuration above, a heating system can be realized which diminishes peak power consumption in the time periods before and after the shut-off period by dividing up the generation of and generating the SOP heat (heat to be radiated in the shut-off period) in the periods before and after the shut-off period.
The heating system control unit may further include: a predicting unit configured to, in each of the periods before and after the shut-off period, predict a shift in generation power consumption which is an amount of power consumed by the heat pump unit for generating heat to maintain the temperature of the target at the set temperature, a shift in additional power consumption which is an amount of power needed for the heat pump unit to generate the divided SOP heat, and a shift in general power consumption which is an amount of power consumed by a device outside of the heating system; and an operation plan unit configured to generate an operation plan for dividing and causing the generation of the SOP heat such that a peak value of overall power consumption in each of the periods before and after the shut-off period is at or below the permissible peak power, the overall power consumption being a total of the general power consumption, the generation power consumption, and the additional power consumption. The heating system control unit is configured to control the heat pump according to the operation plan generated by the operation plan unit.
Moreover, the additional power consumption in the period before the shut-off period may be an amount of power consumed by the heat pump unit to increase the temperature of the target to a pre-SOP goal temperature by a start of the shut-off period, the pre-SOP goal temperature being higher than the set temperature. Similarly, the additional power consumption in the period after the shut-off period may be an amount of power consumed by the heat pump unit to increase the temperature of the target at an end of the shut-off period to the set temperature. Furthermore, the heating system control unit may include a detecting unit configured to detect the temperature of the target and an ambient temperature. The predicting unit may be configured to predict, based on a result of the detection by the detecting unit, the shift in the additional power consumption in each of the periods before and after the shut-off period.
Moreover, the operation plan unit may be configured to select, from among a plurality of the pre-SOP goal temperatures for the peak values of the overall power consumption in each of the periods before and after the shut-off period that are at or below the permissible peak power, the pre-SOP goal temperature for a lowest value of the peak values of the overall power consumption values throughout each of the periods before and after the shut-off period. With this, peaks in power consumption in the periods before and after the shut-off period can be further suppressed.
Moreover, the operation plan unit may be configured to select, from among a plurality of the pre-SOP goal temperatures for the peak values of the overall power consumption in each of the periods before and after the shut-off period that are at or below the permissible peak power, the pre-SOP goal temperature for a lowest temperature of the target during the shut-off period that is greater than or equal to a threshold temperature. With this, peaks in power consumption can be suppressed, and furthermore, since the temperature in the shut-off period does not drop below the threshold temperature, disruption of user comfort can be curtailed.
Moreover, the predicting unit may be configured to predict a shut-off time for each of the plurality of pre-SOP goal temperatures, the shut-off time being a period of time starting when the temperature of the target decreases from the pre-SOP goal temperature and ending when the temperature of the target reaches the threshold temperature. The heating system control unit may be configured to cause the heat pump unit to generate the SOP heat allotted to the period after the shut-off period at a point in time at which the shut-off time corresponding to the selected pre-SOP goal temperature has elapsed from the start of the shut-off period. With this, the comfort level of the user is further maintained.
Furthermore, the operation plan unit may be configured to select, from among the plurality of pre-SOP goal temperatures, the pre-SOP goal temperature which maximizes the shut-off time.
Moreover, the operation plan unit may be configured to execute processing of generating the operation plan upon receiving a signal including information specifying the shut-off period from the power supply source, the signal being received by the operation plan unit a predetermined amount of time before the start of the shut-off period.
Furthermore, the signal further may include information indicating the permissible peak power.
Moreover, the heating system control unit may be configured to receive an input of the permissible peak power from a user.
Moreover, the permissible peak power may be set based on a thermal insulation efficiency of a building in which the heating system is installed.
Moreover, the permissible peak power for the period before the shut-off period and the period after the shut-off period may be set individually so that the permissible peak power for the period before the shut-off period is greater than the permissible peak power for the period after the shut-off period. It is probable that the margin of error for the predicted value of the overall power consumption occurring in the period before the shut-off period is greater than the predicted value of the overall power consumption occurring in the period before the shut-off period. As such, by setting the permissible peak power relatively low for the time period after the shut-off period, peaks in power consumption can be diminished with greater certainty.
Moreover, the heating system may comprise: a heating device including the heat pump unit, the radiator unit, and a heat pump (HP) control unit which controls the heat pump unit in accordance with an instruction from the heating system control unit; and the heating system control unit which is structurally separate from the heating device.
With the foregoing configuration, the heating system control unit can control not only the heating device, but other electronic devices as well. Moreover, when used in an environment in which the shut-off function is not necessary, it is suitable to install simply the heating device.
A method of controlling a heating system according to an embodiment of the present invention receives power from a power supply source and maintains a temperature of a target to within a predetermined temperature range including a predetermined set temperature. The heating system includes a heat pump unit configured to generate heat using power supplied from the power supply source, and a radiator unit configured to radiate the heat generated by the heat pump unit to the target. The method of controlling the heating system comprises causing the heat pump unit to (i) stop generating the heat during a predetermined shut-off period and (ii) generate additional heat as shut-off period (SOP) heat in periods before and after the shut-off period, the SOP heat being an amount of heat required to be radiated during the shut-off period by the radiator unit to maintain the set temperature of the target. In the causing, the generation of the SOP heat is divided between the periods before and after the shut-off period such that a peak value of power consumption in each of the periods before and after the shut-off period is at or below a permissible peak power.
Furthermore, the causing may comprise: predicting, in each of the periods before and after the shut-off period, a shift in generation power consumption which is an amount of power consumed by the heat pump unit for generating heat to maintain the temperature of the target at the set temperature, a shift in additional power consumption which is an amount of power needed for the heat pump unit to generate the divided SOP heat, and a shift in general power consumption which is an amount of power consumed by a device outside of the heating system; and generating an operation plan for dividing and causing the generation of the SOP heat such that a peak value of overall power consumption in each of the periods before and after the shut-off period is at or below the permissible peak power, the overall power consumption being a total of the general power consumption, the generation power consumption, and the additional power consumption. In the causing, the generation of the SOP heat is divided between the periods before and after the shut-off period such that a peak value of power consumption in each of the periods before and after the shut-off period is at or below a permissible peak power.
Moreover, the additional power consumption in the period before the shut-off period may be an amount of power consumed by the heat pump unit to increase the temperature of the target to a pre-SOP goal temperature by a start of the shut-off period, the pre-SOP goal temperature being higher than the set temperature. Similarly, the additional power consumption in the period after the shut-off period may be an amount of power consumed by the heat pump unit to increase the temperature of the target at an end of the shut-off period to the set temperature. Furthermore, the causing may include detecting the temperature of the target and an ambient temperature. In the predicting, the shift in the additional power consumption in each of the periods before and after the shut-off period is predicted based on a result of the detecting.
Moreover, in the generating, the pre-SOP goal temperature for a lowest value of the peak values of the overall power consumption throughout each of the periods before and after the shut-off period may be selected from among a plurality of the pre-SOP goal temperatures for the peak values of the overall power consumption in each of the periods before and after the shut-off period that are at or below the permissible peak power.
Moreover, in the generating, the pre-SOP goal temperature for a lowest temperature of the target during the shut-off period that is greater than or equal to a threshold temperature may be selected from among a plurality of the pre-SOP goal temperatures for the peak values of the overall power consumption in each of the periods before and after the shut-off period that are at or below the permissible peak power.
Moreover, in the predicting, a shut-off time may be predicted for each of the plurality of pre-SOP goal temperatures, the shut-off time being a period of time starting when the temperature of the target decreases from the pre-SOP goal temperature and ending when the temperature of the target reaches the threshold temperature. In the causing, the heat pump unit may be caused to generate the SOP heat allotted to the period after the shut-off period at a point in time at which the shut-off time corresponding to the selected pre-SOP goal temperature has elapsed from the start of the shut-off period.
Furthermore, in the generating, the pre-SOP goal temperature which maximizes the shut-off time may be selected from among the plurality of pre-SOP goal temperatures.
Moreover, in the generating, a process for generating the operation plan may be executed upon receiving a signal including information specifying the shut-off period from the power supply source, the signal being received a predetermined amount of time before the start of the shut-off period.
It is to be noted that general or specific embodiments may be realized as a system, method, integrated circuit, computer program, storage media, or any elective combination thereof.
Hereinafter, embodiments of present invention are described with reference to the Drawings.
It is to be noted that each of the embodiments described below shows a specific example of the present invention. The numerical values, shapes, materials, structural elements, the arrangement and connection of the structural elements, steps, the processing order of the steps etc. shown in the following exemplary embodiments are mere examples, and therefore do not limit the present invention. Moreover, among the structural elements in the following exemplary embodiments, structural elements not recited in any one of the independent claims defining the most generic part of the inventive concept are described as arbitrary structural elements.

[Embodiment 1]

FIG. 1 is a diagram showing a heat pump heating system 1 according to the first embodiment of the present invention. In the example shown in FIG. 1, power is delivered to a home (building) from an energy supplier (power supply source) 4 via a first and second power grid. The first power grid is a network that provides a stable supply of power. Moreover, the first power grid is a power grid having a relatively high electrical utility rate, and the amount of power consumed from the first power grid is measured by a first power meter 6. The second power grid is a power grid from which the energy supplier 4 can stop the supply of power during a given time period. Moreover, the second power grid is a power grid having an electrical utility rate that is lower than that of the first power grid, and the amount of power consumed from the second power grid is measured by a second power meter 7.
Moreover, an electric load 5, a heating system control unit 8, and a heat pump heating device 100 are installed inside the home shown in FIG. 1. The heat pump heating device 100 includes at least a heat pump (heat generation unit) 101, a heat exchanger 102, and a heating device (radiator unit) 103.
The heat pump heating device 100 is a device which, by radiating the heat generated by the heat pump 101 from the heating device 103 using the heat exchanger 102, maintains the temperature of a room in which the heating device 103 is installed to within a predetermined temperature range including a predetermined set temperature. It is to be noted that the predetermined temperature range is, for example, a range in which the greatest value is a pre-SOP goal room temperature (described later) and the lowest value is a threshold temperature (described later).
The first power meter 6 measures the power consumption of electronic devices (that is, an electric load 5) other than the heating system control unit 8 and the heat pump heating device 100. In other words, the heating system control unit 8 and the electric load 5 operate off power supplied from the energy supplier 4 via the first power grid. On the other hand, the second power meter 7 measures the power consumption of components of the heat pump heating device 100 such as the compressor, pump, and fan. In other words, the components of the heat pump heating device 100 operate off power supplied from the energy supplier 4 via the second power grid.
The heating system control unit 8 is functionally capable of communicating with the energy supplier 4 and administering control commands to the heat pump heating device 100. For example, the heating system control unit 8 stops the generation of head by the heat pump heating device 100 during the shut-off period. Furthermore, the heating system control unit 8 causes the heat pump heating device 100 to operate according to an operation plan generated in advance during a time period outside of the shut-off period.
The energy supplier 4 is a company which delivers electricity or gas to individual homes and which can notify each individual home ahead of time with a shut-off signal (hereinafter referred to as a pre-SOP shut-off signal) when the energy supplier 4 wishes to control the use of power by a given home. The notification time of the pre-SOP shut-off signal is, for example, two hours before the energy supplier 4 wishes to control the use of power by a given home.
FIG. 2 is a block diagram showing the heat pump heating device 100 and the heating system control unit 8 according to the first embodiment of the present invention in detail.
The heat pump 101 is an air-source heat pump which compresses a refrigerant (such as R410A) into a high temperature-high pressure state. The heat exchanger 102 facilitates heat exchange between the refrigerant transformed into a high temperature-high pressure state by the heat pump 101 and the secondary side of the water cycle (that is, the water cycling between the heat exchanger 102 and the heating device 103).
The heating device 103 is a device for heating the inside of a home, such as a radiator or floor heater which radiates heat energy in a room via a radiator panel, for example. It is to be noted that a specific example of the heating device 103 is not limited to the foregoing, but corresponds to any device having a radiator unit which radiates heat generated by the heat pump 101 to a target.
An ambient temperature detecting unit 104 is installed outside of the room and detects ambient temperature using a thermostat, for instance. A room temperature detecting unit 105 is installed inside the room and detects room temperature using a thermostat, for instance. It is to be noted that the room temperature detecting unit 105 is an example of a temperature detecting unit which measures temperature of a target (in this case, a room), but is not limited thereto. When the heating device 103 is a floor heater, a temperature detecting unit may be used to detect the temperature of the floor (target) in place of the room temperature detecting unit 105.
An HP control unit 106 controls the amount of heat generated by the heat pump 101 and controls the amount of heat radiated by the heating device 103, such that the temperature of the room in which the heating device 103 is installed is maintained within a predetermined range including the set temperature. It is to be noted that in a normal operating state (that is, in a state in which the pre-SOP shut-off signal is not being received), the HP control unit 106 controls operation of the heat pump 101 and the heating device 103 according to operation conditions set by a user, for example. On the other hand, the HP control unit 106 controls operation of the heat pump 101 and the heating device 103 in accordance with instructions from the heating system control unit 8 in the periods before and after the shut-off period.
The heating system control unit 8 is configured from a state detecting unit 81, a communication unit 82, a predicting unit 83, an operation plan unit 84, a control switching unit 85, and a control instruction unit 86. It is to be noted that in the first embodiment, the heating system control unit 8 is configured to be structurally separate from the heat pump heating device 100. However, a configuration in which the heat pump heating device 100 and the heating system control unit 8 are combined, such as a configuration in which the heating system control unit 8 is placed where in the HP control unit 106 is, is also acceptable.
The state detecting unit 81, ambient temperature detecting unit 104, and the room temperature detecting unit 105 detect (collect) various information such as power consumption amount measured by the first power meter 6 and the second power meter 7, and the amount of heat radiated in each room by the heating device 103, from various detected signals.
The communication unit 82 receives pre-SOP shut-off signals and ON signals from the energy supplier 4, and has a function to notify the energy supplier 4 of the stopping and restarting of the delivery of power to the heat pump heating device 100 via the second power grid. The pre-SOP shut-off signal received by the communication unit 82 is a signal which stops the delivery of power via the second power grid after a predetermined period of time has elapsed.
The pre-SOP shut-off signal includes information which specifies the shut-off period which is a time period during which the delivery of power via at least the second power grid is stopped. For example, the shut-off period used in the examples described hereinafter is a period of one hour lasting from 18:00 to 19:00. The pre-SOP shut-off signal may further include information indicating the permissible peak power for the periods before and after the shut-off period. For example, the permissible peak power used in the examples described hereinafter is 4.5 kW.
The predicting unit 83 includes an algorithm for predicting a shift in the amount of heat needed for heating during the shut-off period, a shift in the power consumption during the periods before and after the shut-off period, and a shift in the amount of decrease in room temperature during the shut-off period, based on information detected by the state detecting unit 81 such as the ambient temperature, room temperature, heater temperature, and power consumption. The predicting method will be described in detail later.
The operation plan unit 84 generates an operation plan for the operation of the heat pump heating device 100 during the periods before and after the shut-off period. The operation plan is generated, for example, at a point in time at which the pre-SOP shut-off signal is received by the communication unit 82 from the energy supplier 4, and is based on the predicted values from the predicting unit 83.
When the control switching unit 85 does not receive the pre-SOP shut-off signal from the communication unit 82 or the energy supplier 4, internal control by the HP control unit 106 inside the heat pump heating device 100 is given priority. However, when the pre-SOP shut-off signal is received, the HP control unit 106 is forced to control each of the foregoing components according to the operation plan generated by the operation plan unit 84 and received by the control instruction unit 86.
The control instruction unit 86 sends the operation plan generated by the operation plan unit 84 to the HP control unit 106 included in the heat pump heating device 100.
Next, operations of the heating system control unit 8 according to the first embodiment will be explained with reference to FIG. 3 through FIG. 5B. FIG. 3 is a flow chart illustrating the processes involved in the generation of the operation plan for the heat pump heating device 100 by the operation plan unit 84 and the predicting unit 83. FIG. 4A is a table showing a power consumption prediction result when the pre-SOP goal room temperature is 24 degrees Celsius. FIG. 4B is a table showing a calculation result of the peak overall power consumption value for each of the pre-SOP goal room temperatures. FIG. 5A is a graph showing shifts in HP heat output and room temperature for each of the pre-SOP goal room temperatures predicted by the predicting unit 83. FIG. 5B is a graph showing shifts in power consumption for each of the pre-SOP goal room temperatures predicted by the predicting unit 83.
The operation plan generated here is an operation plan for generating additional heat in the heat pump 101 during the periods before and after the shut-off period (hereinafter represented as pre-SOP heating period and post-SOP heating period). Here, the additional heat is heat required to be radiated during the shut-off period by the heating device 103 in order to maintain the temperature of the room at the set temperature (hereinafter represented as SOP (shut-off period) heat). More specifically, the operation plan unit 84 generates an operation plan for dividing up the generation of and generating the SOP heat in the pre-SOP heating period and the post-SOP heating period such that the peak power consumption values in the pre-SOP heating period and the post-SOP heating period are each at or below the permissible peak power.
The operation plan unit 84 begins generating the operation plan at a point in time at which the communication unit 82 receives the pre-SOP shut-off signal from the energy supplier 4 (YES in S11). However, the timing of the operation plan generation is not limited to this, and for example may be generated at a predetermined point in time (for example, midnight). In this case, however, knowledge of the shut-off period for that day is required.
First, the operation plan unit 84 selects the pre-SOP goal room temperature (pre-SOP goal temperature) (S12). The pre-SOP goal room temperature is the temperature of the room at the start of the shut-off period. In the example shown in FIG. 3, in one degree increments, a range from 21 to 24 degrees Celsius is selected.
Next, the predicting unit 83 predicts a shift power consumption of the heat pump 101 (hereinafter represented as HP power consumption) during each of the pre-SOP heating period and the post-SOP heating period based on the ambient temperature and the room temperature information detected by the state detecting unit 81 (S13). This predicted value depends on, for example, the efficiency of the heat pump (the rated capacity, COP), the efficiency of the heating device 103, and the thermal efficiency of the home (heat radiation loss, for example).
It is to be noted that the HP power consumption predicted in step S13 is a change over time, during the pre-SOP heating period and the post-SOP heating period, in the sum total value of generation power consumption which is power consumed by the heat pump 101 to maintain the set temperature of the room (power needed to generate an amount of heat corresponding to the heat needed to maintain room temperature shown in FIG. 4A) and additional power consumption which is power needed for the heat pump 101 to generate the divided SOP heat (power needed to generate an amount of heat which corresponds to the room heating amount shown in FIG. 4A).
Furthermore, the predicting unit 83 predicts a shift in the general power consumption (S14). It is to be noted that the general power consumption predicted in step S14 is a change over time in the power consumed by electronic devices other than the heat pump heating device 100 (the electric load 5 in the example shown in FIG. 1).
Lastly, the operation plan unit 84 calculates the peak overall power consumption value for each of the pre-SOP heating period and the post-SOP heating period based on the predicted values (S15). It is to be noted that the overall power consumption calculated in step S15 is a change over time in the sum total value of the generation power consumption, the additional power consumption, and the general power consumption predicted in steps S13 through S14.
Next, a specific example explaining the method of predicting the shift in overall power consumption during the pre-SOP heating period when the pre-SOP goal room temperature is 24 degrees Celsius will be given with reference to FIG. 4A. FIG. 4A shows changes in the variables time, room temperature (degrees Celsius), heat needed to maintain room temperature (W), room heating amount (W), HP power consumption (W), general power consumption (W), and overall power consumption (W).
Here, each of the predicted values shown in FIG. 4A are influenced by room cubic capacity, room surface area, room air specific heat, room thermal insulation efficiency, ambient temperature, and HP efficiency (coefficient of performance). The example shown in FIG. 4A is a prediction result when the room cubic capacity is 500 m³, the room surface area is 600 m², the air specific heat is 0.34 Wh / degrees Celsius m³, the room thermal insulation efficiency is 0.5 W / degrees Celsius m², the ambient temperature is 0 degrees Celsius, and the HP coefficient of performance (COP) is 3.
In FIG. 4A, the set temperature for the room at 17:00 is 20 degrees Celsius. The set temperature of the heat pump heating device 100 is such that the temperature of the room is 20 degrees Celsius outside of the pre-SOP heating period, shut-off period, and the post-SOP heating period. From 17:00, the room temperature gradually begins to rise. Fifteen minutes later at 17:15 the room temperature rises to 21 degrees Celsius. Similarly, at 17:30 the room temperature is 22 degrees Celsius, 23 degrees Celsius at 17:45, and 24 degrees Celsius at 18:00, which is the pre-SOP goal temperature. That is, FIG. 4A shows an example in which the room temperature rises from the set temperature of 20 degrees Celsius to the pre-SOP goal room temperature of 24 degrees Celsius in a period of one hour from 17:00 to 18:00 (the pre-SOP heating period) at a rate of 1 degree Celsius every 15 minutes.
The amount of heat needed to raise the room temperature from 20 degrees to 21 degrees Celsius in a span of 15 minutes from 17:00 to 17:15 is the sum of the heat needed to maintain room temperature and the room heating amount, where the heat needed to maintain room temperature is the power consumed in order to maintain the room temperature of 20 degrees Celsius, and the room heating amount is the power needed in order to increase the room temperature by 1 degree Celsius.
Here, heat needed to maintain room temperature can be calculated using Equation 1, and room heating amount can be calculated using Equation 2. That is, the amount of heat radiated from the heating device 103 in the fifteen minutes between 17:00 and 17:15 is 600 (Equation 1) + 748 (Equation 2) = 6748 W. $heat needed to maintain room temperature = (room temperature - ambient temperature) \times thermal insulation efficiency \times room surface area$
$room heating amount = change in temperarture \times air specific heat \times room cubic capacity / heating time$
Moreover, the HP power consumption, which is the power consumed by the heat pump 101 in order to generate the room heating amount and the heat needed to maintain room temperature, can be calculated with Equation 3. That is, the HP power consumption in the fifteen minutes between 17:00 and 17:15 is 2249 W. $HP power consumption = (room heating amount + heat needed to maintain room temperature) / COP$
Furthermore, the general power consumption, which is the power consumed by, for example, home electronics (electric load 5) in the fifteen minutes between 17:00 and 17:15, is 1640 W. Thus, the overall power consumption in the fifteen minutes between 17:00 and 17:15 is 2249 + 1640 = 3889 W.
It is to be noted that the prediction method for the general power consumption is not particularly limited. For example, it is acceptable to predict the general power consumption based on past actual power consumption performance. For example, the power consumption measured by the first power meter 6 can be collected by the state detecting unit 81 on a regular basis and stored. It is then acceptable to use a predicted value that is the average of actual power consumption performances from the past in the same day of the week and time of day as the target time period for prediction (for example, 3 values taken from 1 week ago, 2 weeks ago, and 3 weeks ago).
The overall power consumption in the fifteen minutes between 17:15 and 17:30 is 3909 W, 3769 W in the fifteen minutes between 17:30 and 17:45, and 4000 W in the fifteen minutes between 17:45 and 18:00. Next, as shown in FIG. 4A, the peak overall power consumption value in the pre-SOP heating period between 17:00 and 18:00 is 4000 W (4 kW).
Similarly, the shift in overall power consumption in the post-SOP heating period can be calculated. It is to be noted that here, HP power consumption is the power consumed by the heat pump 101 in order to generate an amount of heat equivalent to the sum of the heat needed to maintain room temperature which is the power consumed in order to maintain the room temperature at the end of the shut-off period, and the room heating amount which is the power needed in order to increase the room temperature to the set temperature.
For example, when the room temperature at the end of the shut-off period is 18 degrees Celsius and the room temperature is raised for 30 minutes until the set temperature of 20 degrees Celsius is reached at a rate of 1 degree Celsius per fifteen minutes, the operation plan unit 84 calculates the heat needed to maintain room temperature and the room heating amount for each 15 minute period using Equation 1 and Equation 2, and uses the calculated values to find the peak overall power consumption value.
It is to be noted that in the foregoing example, the pre-SOP heating period is one hour, and the post-SOP heating period is 30 minutes, but the time can be changed voluntarily. It is also to be noted that as the length of time increases, the peaks in power consumption decrease, but radiant heat loss increases leading to an increased power consumption load. On the other hand, as the length in time decreases, radiant heat loss decreases, but peaks in power consumption increase. Furthermore, when the length of time is too short, the change in temperature becomes drastic, compromising user comfort.
For that reason, the length of the heating periods may be changed according to the change in temperature. That is, the pre-SOP heating period can be set longer for higher pre-SOP goal room temperatures, and the post-SOP heating period can be set longer for greater differences between the room temperature predicted value at the end of the shut-off period and the set temperature. As a result, the comfort of the user is not compromised, and an increase in the peaks in power consumption can be avoided.
Next, for each of the selected pre-SOP goal room temperatures, the operation plan unit 84 saves the peak overall power consumption value calculated in step S15, and repeats the sequence of actions in steps S12 through S15 (S16). The result is a chart of the peak overall power consumption value for each of the pre-SOP goal room temperatures, such as the one shown in FIG. 4B. It is to be noted that shown in the peak overall power consumption value column on the right are the peak overall power consumption values throughout both the pre-SOP heating period and the post-SOP heating period.
Lastly, the operation plan unit 84 selects the pre-SOP goal room temperatures for the peak overall power consumption values that are at or below the permissible peak power (S17). For example, if the permissible peak power is 4.5 kW, the selected pre-SOP goal room temperatures among those shown in FIG. 4B would be 23 degrees and 24 degrees Celsius, because the corresponding peak overall power consumption values are at or below the permissible peak power. Next, the operation plan unit 84 according to the first embodiment selects 24 degrees Celsius which corresponds to the lowest of the peak overall power consumption values.
Next, the control instruction unit 86 notifies the HP control unit 106 of the operation plan (for example, the chart in FIG. 4A corresponds to the operation plan for the pre-SOP heating period) for the pre-SOP heating period and the post-SOP heating period generated by the operation plan unit 84. The HP control unit 106 then controls operation of the heat pump 101 according to the received operation plan.
Specifically, the HP control unit 106 controls operation of the heat pump 101 and the heating device 103 such that the temperature of the room in which the heating device 103 is installed rises by 4 degrees Celsius at a rate of one degree every 15 minutes for one hour between 17:00 and 18:00, which is the pre-SOP heating period. In other words, the temperature is raised from the set temperature of 20 degrees Celsius to the pre-SOP goal room temperature of 24 degrees Celsius in this span of one hour. Similarly, the HP control unit 106 controls operation of the heat pump 101 and the heating device 103 such that the temperature of the room in which the heating device 103 is installed rises by 2 degrees Celsius at a rate of one degree every 15 minutes for 30 minutes between 19:00 and 19:30, which is the post-SOP heating period. In other words, the room temperature at the end of the shut-off period of 18 degrees Celsius is brought back up to the set temperature of 20 degrees Celsius in this span of 30 minutes.
As a result of the operation control described above, shifts in the HP heat output, room temperature, and overall power consumption are predicted as shown in FIG. 5A and FIG. 5B. However, there is a possibility that the actual result will not match this prediction result exactly. Specifically, the HP heat output, room temperature, and overall power consumption monotonically increase such that the room temperature at the end of the pre-SOP heating period reaches the pre-SOP goal room temperature. Next, in the shut-off period (represented as SOP in the Drawings), the HP heat output is 0 (that is, the heat pump 101 is stopped), the room temperature monotonically decreases, and the power consumption becomes simply general power consumption. Then, the HP heat output, room temperature, and overall power consumption monotonically increase such that the room temperature at the end of the post-SOP heating period reaches the pre-SOP goal room temperature.
No matter which is chosen, each of the pre-SOP goal room temperatures show the same trend in HP heat output, room temperature, and overall power consumption shifts, but as is shown in FIG. 5A and FIG. 5B, the higher the pre-SOP goal room temperature is, the higher the temperature to be increased in the pre-SOP heating period becomes, the higher the HP heat output becomes, and the higher the HP power consumption becomes. On the other hand, operation of the heat pump 101 stops during the shut-off period and heat ceases to radiate from the heating device 103, thereby causing the room temperature to decrease. Moreover, the room temperature at the end of the shut-off period increases for higher ones of the pre-SOP goal room temperatures. Consequently, the higher the pre-SOP goal room temperature, the lower the HP heat output and the HP power consumption for bringing back up the temperature of the room to the set temperature in the post-SOP heating period are.
Thus, according to the first embodiment, SOP heat required to be radiated from the heating device 103 during the shut-off period to maintain the set temperature of the room can be suitably divided and generated in the pre-SOP heating period and the post-SOP heating period by predicting a shift in overall power consumption for each pre-SOP goal room temperature. As a result, the peak overall power consumption values in the periods before and after the shut-off period can be equalized at or below the permissible peak power.

[Embodiment 2]

The configuration of the heat pump heating system 1 according to the second embodiment is the same as the first embodiment, and as such explanation thereof will be omitted. The explanation will therefore focus on the points of difference, and details regarding common points with the first embodiment will also be omitted.
According to the first embodiment, a shift in overall power consumption is predicted for each pre-SOP goal room temperature, and the pre-SOP goal room temperatures for the peak overall power consumption values which are at or below the permissible peak power are selected. However, depending on the thermal efficiency of the home, the room temperature can drastically decrease due to the dissipation of heat during the shut-off period, causing the comfort of the user of the heat pump heating device 100 to be compromised.
With this in mind, according to the second embodiment, an approach is taken to keep the peak overall power consumption value at or below the permissible peak power while also maintaining a room temperature which does not compromise the comfort of the user of the heat pump heating device 100, by further predicting a shift in the amount of decrease in room temperature during the shut-off period.
Next, operations of the heating system control unit 8 according to the second embodiment will be explained with reference to FIG. 6 and FIG. 7. FIG. 6 is a flow chart illustrating the processes involved in the generation of the operation plan for the heat pump heating device 100 by the operation plan unit 84 and the predicting unit 83 according to the second embodiment of the present invention. FIG. 7 is a table showing a calculation result of the peak overall power consumption value for each of the pre-SOP goal room temperatures.
The points of difference from the flow chat shown in FIG. 3 according to the first embodiment are that the lowest room temperature is at or above the permissible room temperature after a shift in the amount of decrease in room temperature during the shut-off period is predicted based on the ambient temperature and the room temperature information, and that the pre-SOP goal room temperatures for the peak overall power consumption values that are at or below the permissible peak power are selected. The steps S12, S13, S14, S15, and S16 in FIG. 6 perform the same functions as in the first embodiment (FIG.3).
In step S21 in FIG. 6, the predicting unit 83 predicts the amount of decrease in room temperature during the shut-off period, and saves the lowest room temperature (usually the room temperature at the end of the shut-off period) for each of the pre-SOP goal room temperatures, as is shown in FIG. 7. Next, in step S22, the operation plan unit 84 selects the pre-SOP goal room temperatures for the shut-off period lowest room temperatures that are at or above a threshold value (permissible room temperature) from among the plurality of pre-SOP goal room temperatures for the peak overall power consumption values that are at or below the permissible peak power.
For example, when the permissible room temperature is 16 degrees Celsius and the permissible peak power is 4.5 kW, the operation plan unit 84 selects, from among the plurality of pre-SOP goal room temperatures for the peak overall power consumption values that are at or below the permissible peak power (23, 24, and 25 degrees Celsius), the temperature of 25 degrees Celsius which corresponds to the shut-off period lowest room temperature that is at or above the permissible room temperature, as is shown in FIG. 7.
It is to be noted that when there is a plurality of pre-SOP goal room temperatures which meet the permissible peak power condition and whose shut-off period lowest room temperatures are at or above the permissible room temperature, the pre-SOP goal room temperature for the lowest of the peak overall power consumption values among them may be selected.
In this way, according to the second embodiment, by predicting a shift in overall power consumption and in the amount of decrease in room temperature for each pre-SOP goal room temperature, selection of a pre-SOP goal room temperature can be made whereby the peak power consumption value will not exceed the permissible peak power, and whereby room temperature will not drop to or below the permissible room temperature. As a result, the peak overall power consumption values in the periods before and after the shut-off period can be equalized at or below the permissible peak power while also maintaining a room temperature which does not compromise the comfort of the user of the heat pump heating device 100.

[Embodiment 3]

The configuration of the heat pump heating system 1 according to the third embodiment is the same as the first embodiment, and as such explanation thereof will be omitted. The explanation will therefore focus on the points of difference, and details regarding common points with the first and second embodiments will also be omitted.
The second embodiment focuses on the amount of decrease in room temperature during the shut-off period, wherein a pre-SOP goal room temperature is selected which will keep the room temperature from dropping below the permissible room temperature and keep the peak power consumption value to a minimum. However, from the viewpoint of equalization of the overall power consumption, optimum control is not necessarily achieved in every case.
For that reason, with the third embodiment, a shift in the amount of decrease in room temperature during the shut-off period is predicted for each pre-SOP goal room temperature, and after determining a shut-off time which will not compromise the comfort of the user of the heat pump heating device 100, the peak overall power consumption values are compared.
Next, operations of the heating system control unit 8 according to the third embodiment will be explained with reference to FIG. 8 through FIG. 10. FIG. 8 is a flow chart illustrating the processes involved in the generation of the operation plan for the heat pump heating device 100 by the operation plan unit 84 and the predicting unit 83 according to the third embodiment of the present invention. FIG. 9A is a graph showing shifts in HP heat output and room temperature for each of the pre-SOP goal room temperatures predicted by the predicting unit 83. FIG. 9B is a graph showing shifts in power consumption for each of the pre-SOP goal room temperatures predicted by the predicting unit 83. FIG. 10 is a table showing calculation results of the peak overall power consumption value for each of the pre-SOP goal room temperatures.
The point of difference from the flow chart shown in FIG. 3 according to the first embodiment the addition of a process in which a shift in the decrease in room temperature during the shut-off period using the ambient temperature and the room temperature information is predicted and a shut-off time is determined. The steps S12, S13, S14, S15, and S16 in FIG. 8 perform the same functions as in the first embodiment (FIG.3).
The heat pump heating system according to the third embodiment can restart the supply of power to the heat pump 101 before the end of the shut-off period indicated in the pre-SOP shut-off signal. However, before the original end time of the shut-off period, the heat pump 101 operates off of a supply of power received via the first power grid from the energy supplier 4.
Specifically, in step S31, the predicting unit 83 predicts a shift in the amount of decrease in room temperature during the shut-off period and determines a shut-off time. Here, the shut-off time is a period of time beginning when the room temperature decreases from the pre-SOP goal temperature and ending when the room temperature reaches the threshold temperature (permissible room temperature). In other words, it is a time period during which the supply of power to the heat pump 101 is truly cut off.
Moreover, in step S32, with consideration of the shut-off time, the operation plan unit 84 selects a pre-SOP goal temperature from among the plurality of pre-SOP goal temperatures for the peak overall power consumption values that are at or below the permissible peak power.
As is shown in FIG. 9A and FIG. 9B, the higher the pre-SOP goal room temperature, the greater the overall power consumption in the pre-SOP heating period increases, but the amount of time it takes for the room temperature to reach the permissible room temperature also increases. In other words, the degree that the shut-off period can be shortened decreases. On the other hand, the lower the pre-SOP goal room temperature, the lesser the overall power consumption in the pre-SOP heating period is, but the amount of time it takes for the room temperature to reach the permissible room temperature becomes shorter. In other words, the shut-off period can be shortened to a greater degree.
For this reason, the operation plan unit 84 may determine the pre-SOP goal room temperature upon consideration of the balance between the peak overall power consumption value and the breadth of the shut-off period. For example, when the permissible room temperature is 18 degrees Celsius and the permissible peak power is 4.5 kW, the operation plan unit 84 may select, from among the plurality of pre-SOP goal room temperatures for the peak overall power consumption values that are at or below the permissible peak power (21, 22, 23, 24, 25, and 26 degrees Celsius), the temperature of 23 degrees Celsius which corresponds to the lowest of the peak overall power consumption values, as is shown in FIG. 10. However, the selection method of the pre-SOP goal room temperature is not limited to this method. For instance, the operation plan unit 84 may select, from among the plurality of pre-SOP goal room temperatures which meet the permissible peak power condition, the temperature of 25 degrees Celsius which maximizes the shut-off time.
When the operation plan unit 84 selects 23 degrees Celsius, the heating system control unit 8 causes the heat pump 101 to restart generating heat before the end of the shut-off period as originally specified by the energy supplier 4. Specifically, the heating system control unit 8 causes the heat pump 101 to generate the SOP heat allotted to the post-SOP heating period at a point in time at which the shut-off time corresponding to the selected pre-SOP goal temperature has elapsed from the start of the shut-off period. That is, according to the third embodiment, the point in time at which the shut-off period ends and the point in time at which the post-SOP heating period starts and ends varies depending on the pre-SOP goal room temperature selected, as is shown in FIG. 9A and FIG. 9B.
As such, with the third embodiment, by predicting a shift in the overall power consumption and the amount of decrease in room temperature for each of the pre-SOP goal room temperatures, and by further predicting a shut-off time such that room temperature will not drop to or below the permissible room temperature, the peak overall power consumption values in the periods before and after the shut-off period can be equalized at or below the permissible peak power while also maintaining a room temperature which does not compromise the comfort of the user of the heat pump heating device 100
While the permissible peak power was set as notified by the energy supplier 4 in the first, second, and third embodiments, it is also acceptable to set the permissible peak power with the method described below. For example, the permissible peak power may be stored and set in the heating system control unit 8 by the user for each individual home.
FIG. 11 shows the correlation of the heating surface area and the permissible peak power. If the heating surface area is a room that is 50 m², the permissible peak power is set to 4 kW. In this way, the permissible peak power may be set according to the flooring surface area to which heat is supplied.
FIG. 12 shows the correlation of the rated capacity of the heat pump heating device and the permissible peak power. If the rated capacity is 6 kW, then the permissible peak power is set to 4 kW. In this way, the permissible peak power may be set according to the rated capacity of the heat pump heating device 100.
Moreover, the energy supplier 4 may include with the pre-SOP shut-off signal and send a chart of the permissible peak powers corresponding to the flooring surface area to the heating system control unit 8, such as the one shown in FIG. 11. The heating system control unit 8 may then obtain the flooring surface area of the room in which the heating device 103 is installed and select the permissible peak power corresponding to the flooring surface area obtained from the chart included in the pre-SOP shut-off signal.
Moreover, the energy supplier 4 may include with the pre-SOP shut-off signal and send a chart of the permissible peak powers corresponding to the rated capacity to the heating system control unit 8, such as the one shown in FIG. 12. The heating system control unit 8 may then obtain the rated capacity of the heat pump heating device 100 and select the permissible peak power corresponding to the rated capacity obtained from the chart included in the pre-SOP shut-off signal.
Moreover, the user of the heat pump heating device 100 may predict a suitable permissible peak power based on the ambient temperature and current room temperature information at the point in time the shut-off signal or the pre-SOP shut-off signal is received and set the permissible peak power in the heating system control unit 8. With this, a suitable permissible peak power can be set based on environment information such as the ambient temperature and room temperature information at the point in time the shut-off period starts. As a result, equalization of power consumption to within the range of the permissible room temperature in which comfort levels are maintained can be achieved.
In the first, second, and third embodiments, the permissible peak power is handled as a fixed value in relation to a temporal period, that is, in relation to the pre-SOP heating period and the post-SOP heating period. However, the permissible peak power may vary temporally, as described below. For example, the permissible peak power for the post-SOP heating period may be set individually so as to be lower than the permissible peak power for the pre-SOP heating period. This is because, upon consideration of the home-wide electrical needs and prediction margin of error for heating load, there is a high probability that the prediction margin of error for the predicted value of the overall power consumption occurring in the post-SOP heating period will be greater than the prediction margin of error for the predicted value of the overall power consumption occurring in the pre-SOP heating period. For this reason, is it possible to reduce an increase in the peak power arising from a difference in the peak power predicted value and the actual value by estimating the permissible peak power for the post-SOP heating period on the low side.
It should be noted that although the present invention was described based on the previous embodiments, the present invention is not limited to these embodiments. The following examples are also intended to be included within the scope of the present invention.
Each of the preceding devices is, specifically, a computer system configured from a microprocessor, ROM, RAM, a hard disk unit, a display unit, a keyboard, and a mouse, for example. A computer program is stored in the RAM or the hard disk unit. Each of the devices achieves its function as a result of the microprocessor operating according to the computer program. Here, the computer program is configured of a plurality of pieced together instruction codes indicating a command to the computer in order to achieve a given function.
A portion or all of the components of each of the preceding devices may be configured from one system LSI (Large Scale Integration). A system LSI is a super-multifunction LSI manufactured with a plurality of components integrated on a single chip, and is specifically a computer system configured of a microprocessor, ROM, and RAM, for example. A computer program is stored in the RAM. The system LSI achieves its function as a result of the microprocessor operating according to the computer program.
A portion or all of the components of each of the preceding devices may each be configured from a detachable IC card or a stand-alone module. The IC card and the module are computer systems configured from a microprocessor, ROM, and RAM, for example. The IC card and the module may include the super-multifunction LSI described above. The IC card and the module achieve their function as a result of the microprocessor operating according to a computer program. The IC card and the module may be tamperproof.
The present invention may be a method shown above. Moreover, the present invention may also be a computer program realizing these methods with a computer, or a digital signal of the computer program.
Moreover, the present invention may also be realized as the computer program or the digital signal stored on storage media readable by a computer, such as a flexible disk, hard disk, CD-ROM, MO, DVD, DVD-ROM, DVD-RAM, DVD-RAM, BD (Blu-ray Disc), or a semiconductor memory. The present invention may also be the digital signal stored on the above mentioned storage media.
Moreover, the present invention may also be realized by transmitting the computer program or the digital signal, for example, via an electric communication line, a wireless or wired line, a network such as the Internet, or data broadcasting.
Moreover, the present invention may be a computer system including memory storing the computer program and a microprocessor operating according to the computer program.
Moreover, the computer program or the digital signal may be implemented by an independent computer system by being stored on the storage media and transmitted, or sent via the network, for example.
The preceding embodiments and the preceding transformation examples may be individually combined.

[Industrial Applicability]

The heat pump heating system and method of controlling the heat pump heating system according to the present invention is useful as a heating system which contributes to the stabilization of grid power.

[Reference Signs List]

1: heat pump heating system
4: energy supplier
5: electric load
6: first power meter
7: second power meter
8: heating system control unit
81: state detecting unit
82: communication unit
83: predicting unit
84: operation plan unit
85: control switching unit
86: control instruction unit
100: heat pump heating device
101: heat pump
102: heat exchanger
103: heating device
104: ambient temperature detecting unit
105: room temperature detecting unit
106: HP control unit

Claims

A heating system (1) which receives power from a power supply source (4) and maintains a temperature of a target to within a predetermined temperature range including a predetermined set temperature, the heating system comprising:
a heat pump unit (101) configured to generate heat using power supplied from the power supply source;

a radiator unit (103) configured to radiate the heat generated by the heat pump unit to the target; and

a heating system control unit (8) configured to cause the heat pump unit to stop generating the heat during a predetermined shut-off period, characterised in that the heating system control unit causes the heat pump unit to generate additional heat as shut-off period (SOP) heat in periods before and after the shut-off period, the SOP heat being an amount of heat required to be radiated during the shut-off period by the radiator unit to maintain the set temperature of the target,

wherein the heating system control unit is configured to cause the generation of the SOP heat to be divided between the periods before and after the shut-off period such that a peak value of power consumption in each of the periods before and after the shut-off period is at or below a permissible peak power.
The heating system according to Claim 1,
wherein the heating system control unit (8) further includes:
a predicting unit (83) configured to, in each of the periods before and after the shut-off period, predict a shift in generation power consumption which is an amount of power consumed by the heat pump unit for generating heat to maintain the temperature of the target at the set temperature, a shift in additional power consumption which is an amount of power needed for the heat pump unit to generate the divided SOP heat, and a shift in general power consumption which is an amount of power consumed by a device outside of the heating system; and

an operation plan unit (84) configured to generate an operation plan for dividing and causing the generation of the SOP heat such that a peak value of overall power consumption in each of the periods before and after the shut-off period is at or below the permissible peak power, the overall power consumption being a total of the general power consumption, the generation power consumption, and the additional power consumption, and

the heating system control unit (8) is configured to control the heat pump (101) according to the operation plan generated by the operation plan unit (84).
The heating system according to Claim 2,
wherein the additional power consumption in the period before the shut-off period is an amount of power consumed by the heat pump (101) unit to increase the temperature of the target to a pre-SOP goal temperature by a start of the shut-off period, the pre-SOP goal temperature being higher than the set temperature,
the additional power consumption in the period after the shut-off period is an amount of power consumed by the heat pump unit (101) to increase the temperature of the target at an end of the shut-off period to the set temperature,
the heating system control unit (8) further includes a detecting unit configured to detect the temperature of the target and an ambient temperature, and
the predicting unit (83) is configured to predict, based on a result of the detection by the detecting unit, the shift in the additional power consumption in each of the periods before and after the shut-off period.
The heating system according to Claim 3,
wherein the operation plan unit (84) is configured to select, from among a plurality of the pre-SOP goal temperatures for the peak values of the overall power consumption in each of the periods before and after the shut-off period that are at or below the permissible peak power, the pre-SOP goal temperature for a lowest value of the peak values of the overall power consumption throughout each of the periods before and after the shut-off period.
The heating system according to Claim 3,
wherein the operation plan (84) unit is configured to select, from among a plurality of the pre-SOP goal temperatures for the peak values of the overall power consumption in each of the periods before and after the shut-off period that are at or below the permissible peak power, the pre-SOP goal temperature for a lowest temperature of the target during the shut-off period that is greater than or equal to a threshold temperature.
The heating system according to Claim 5,
wherein the predicting unit (83) is further configured to predict a shut-off time for each of the plurality of pre-SOP goal temperatures, the shut-off time being a period of time starting when the temperature of the target decreases from the pre-SOP goal temperature and ending when the temperature of the target reaches the threshold temperature, and
the heating system control unit (8) is configured to cause the heat pump unit to generate the SOP heat allotted to the period after the shut-off period at a point in time at which the shut-off time corresponding to the selected pre-SOP goal temperature has elapsed from the start of the shut-off period.
The heating system according to Claim 6, wherein the operation plan unit (84) is configured to select, from among the plurality of pre-SOP goal temperatures, the pre-SOP goal temperature which maximizes the shut-off time.
The heating system according to any one of Claim 2 to Claim 7,
wherein the operation plan unit (84) is configured to execute processing of generating the operation plan upon receiving a signal including information specifying the shut-off period from the power supply source, the signal being received by the operation plan unit a predetermined amount of time before the start of the shut-off period.
The heating system according to Claim 8,
wherein the signal further includes information indicating the permissible peak power.
The heating system according to any one of Claim 1 to Claim 8,
wherein the heating system control unit (8) is configured to receive an input of the permissible peak power from a user.
The heating system according to Claim 10,
wherein the permissible peak power is set based on a thermal insulation efficiency of a building in which the heating system is installed.
The heating system according to any one of Claim 9 to Claim 11,
wherein the permissible peak power for the period before the shut-off period and the period after the shut-off period are set individually so that the permissible peak power for the period before the shut-off period is greater than the permissible peak power for the period after the shut-off period.
The heating system according to any one of Claim 1 to Claim 12, comprising:
a heating device including the heat pump unit (101), the radiator unit (103), and a heat pump (HP) control unit (106) which controls the heat pump unit in accordance with an instruction from the heating system control unit (8); and

the heating system control unit (8) which is structurally separate from the heating device.
A method of controlling a heating system which receives power from a power supply source and maintains a temperature of a target to within a predetermined temperature range including a predetermined set temperature,
the heating system including a heat pump unit (101) configured to generate heat using power supplied from the power supply source, and
a radiator unit (103) configured to radiate the heat generated by the heat pump unit to the target,
the method of controlling the heating system comprising:
causing the heat pump unit (101) to (i) stop generating the heat during a predetermined shut-off period and characterised in that the method of controlling the heating system further causes the heat pump unit to (ii) generate additional heat as shut-off period (SOP) heat in periods before and after the shut-off period, the SOP heat being an amount of heat required to be radiated during the shut-off period by the radiator unit to maintain the set temperature of the target,

wherein in the causing, the generation of the SOP heat is divided between the periods before and after the shut-off period such that a peak value of power consumption in each of the periods before and after the shut-off period is at or below a permissible peak power.
The method of controlling the heating system according to Claim 14,
wherein the causing further comprises:
predicting, in each of the periods before and after the shut-off period, a shift in generation power consumption which is an amount of power consumed by the heat pump unit (101) for generating heat to maintain the temperature of the target at the set temperature, a shift in additional power consumption which is an amount of power needed for the heat pump unit to generate the divided SOP heat, and a shift in general power consumption which is an amount of power consumed by a device outside of the heating system; and

generating an operation plan for dividing and causing the generation of the SOP heat such that a peak value of overall power consumption in each of the periods before and after the shut-off period is at or below the permissible peak power, the overall power consumption being a total of the general power consumption, the generation power consumption, and the additional power consumption,

wherein in the causing, the heat pump is controlled according to the operation plan generated in the generating.
The method of controlling the heating system according to Claim 15,
wherein the additional power consumption in the period before the shut-off period is an amount of power consumed by the heat pump unit to increase the temperature of the target to a pre-SOP goal temperature by a start of the shut-off period, the pre-SOP goal temperature being higher than the set temperature,
the additional power consumption in the period after the shut-off period is an amount of power consumed by the heat pump unit to increase the temperature of the target at an end of the shut-off period to the set temperature,
the causing further includes detecting the temperature of the target and an ambient temperature, and
in the predicting, the shift in the additional power consumption in each of the periods before and after the shut-off period is predicted based on a result of the detecting.
The method of controlling the heating system according to Claim 16,
wherein in the generating, the pre-SOP goal temperature for a lowest value of the peak values of the overall power consumption throughout each of the periods before and after the shut-off period is selected from among a plurality of the pre-SOP goal temperatures for the peak values of the overall power consumption in each of the periods before and after the shut-off period that are at or below the permissible peak power.
The method of controlling the heating system according to Claim 16,
wherein in the generating, the pre-SOP goal temperature for a lowest temperature of the target during the shut-off period that is greater than or equal to a threshold temperature is selected from among a plurality of the pre-SOP goal temperatures for the peak values of the overall power consumption in each of the periods before and after the shut-off period that are at or below the permissible peak power.
The method of controlling the heating system according to Claim 18,
wherein in the predicting, a shut-off time is further predicted for each of the plurality of pre-SOP goal temperatures, the shut-off time being a period of time starting when the temperature of the target decreases from the pre-SOP goal temperature and ending when the temperature of the target reaches the threshold temperature, and
in the causing, the heat pump unit (101) is caused to generate the SOP heat allotted to the period after the shut-off period at a point in time at which the shut-off time corresponding to the selected pre-SOP goal temperature has elapsed from the start of the shut-off period.
The method of controlling the heating system according to Claim 19,
wherein in the generating, the pre-SOP goal temperature which maximizes the shut-off time is selected from among the plurality of pre-SOP goal temperatures.
The method of controlling the heating system according to any one of Claim 15 to Claim 20,
wherein in the generating, a process for generating the operation plan is executed upon receiving a signal including information specifying the shut-off period from the power supply source (4), the signal being received a predetermined amount of time before the start of the shut-off period.